CH702009A1 - Method for optimizing a textile production process. - Google Patents

Abstract

The process serves to optimize a textile production process (101) in which a textile end product is produced. The production process (101) is mapped in a mathematical model (102) that contains a set of parameters ({x 1, ..., x n}) with at least one parameter (x 1, ..., x n) as an element. At least one variation parameter (x i;) from the parameter set ({x 1,..., X n}) is varied (106) by one variation (Δx i) in the model (102). An effect of the at least one variation (Δx i) on a financial value (P) of the final product is assessed (108). Depending on the outcome of the evaluation (108), the at least one variation (Δx i) is adopted in the production process (109).

Description

AREA OF EXPERTISE

The invention is in the field of textile production, in particular spinning. It relates to a method for optimizing a textile production process, a computer program product for carrying out the method and a textile company according to the independent patent claims.

STATE OF THE ART

In textile factories, raw materials or intermediate products are processed into an end product of the production process in a textile production process. A spinning mill, for example, processes raw cotton into a yarn in several processing steps using intermediate products such as sliver. The raw cotton and the intermediate products go through various processing steps such as opening, cleaning, carding, combing, drawing, pre-spinning, fine spinning and finally winding in various work stations.

[0003] WO-2005/054 551 A1 describes a method and a device for order control of a manufacturing process for a fiber product. In order to control and monitor a production order on which the production process is based, an actual / target evaluation is carried out between a target specification predetermined by the production order and an actual state of the production process. The resulting deviation from the target is displayed. This enables planning for the execution of production orders. The teaching of WO-2005/05455 \ A1 is concerned with the production time and the production quantity, but not with the financial value and the quality of the end product.

DISCLOSURE OF THE INVENTION

[0004] It is an object of the present invention to specify a method which further optimizes a textile production process.

[0005] These and other objects are achieved by the method, the computer program product, the textile company, as defined in the independent claims. Advantageous embodiments are specified in the dependent claims.

[0006] The invention is based on the idea of taking into account the financial value of the end product - or the price to be achieved with the end product - in the optimization. Parameters are varied in a mathematical model of the production process and the effect of the variation on the financial value is calculated. An assessment of the effects, which may include other aspects such as the resulting quality of the end product and / or the production time, leads to the decision as to whether the variation is to be incorporated into the production process or not.

Accordingly, in the inventive method for optimizing a textile production process in which a textile end product is produced, the production process is mapped in a mathematical model that contains a set of parameters with at least one parameter as an element. At least one variation parameter from the set of parameters is varied by one variation in the model. An effect of the at least one variation on a financial value of the end product is assessed.

The corresponding models, algorithms and formulas used for the calculations are known per se, e.g. from the following publications: W. Klein, "The Technology of Short-Stack Spinning," The Textile Institute, 2nd ed., 1998 "Rieter Spinning Documentation", Rieter Marketing, 1999 "Short-staple spinning", Bräcker AG, 2008.

You therefore do not need to be explained further here.

In a preferred embodiment of the method according to the invention, depending on the outcome of the evaluation, the at least one variation is adopted in the production process. The textile production process is z. B. spinning or winding yarn, and the at least one variation parameter is selected from the following quantity: number of cuts per yarn length or per unit of time, proportion of noils during combing, number of end breaks during ring spinning, replacement time of the ring traveler during ring spinning, delivery speed of the draw frame, quality the raw cotton, proportion of outliers in the yarn. In addition to the financial value, other aspects such as the quality of the end product and production time can be included in the assessment. A choice of the variation parameter, a choice of the parameter values and / or a choice of the variation are preferably made in such a way that the quality of the end product remains approximately the same or is at least not significantly reduced. A choice of the at least one variation parameter and / or the choice of the at least one variation can be carried out automatically by a computer. A user interface with fields for inputs and outputs is preferably provided on an electronic display unit, which is advantageously displayed on a single screen page.

The computer program product according to the invention contains program code stored on a machine-readable carrier for carrying out the method according to the invention when the program product runs on a computer.

The textile company according to the invention is set up to carry out a textile production process and includes a computer on which the computer program product according to the invention runs.

LIST OF DRAWINGS

The invention and an advantageous embodiment will now be described in more detail with reference to drawings. 1 <sep> shows a flow diagram with the method according to the invention. FIG. 2 <sep> shows an embodiment of a user interface as can be made available in the method according to the invention for optimizing a yarn winding process.

CARRYING OUT THE INVENTION

1 shows the basic idea of the method according to the invention in a flow chart. The starting point is a textile company in which a textile production process 101 is carried out. This is, for example, a spinning mill that produces yarn as the end product from raw cotton delivered in bales as the starting product. Intermediate processes in this production process 101, which are carried out by different work stations, are, for example: opening, cleaning, mixing, carding, doubling, combing, drawing, spinning and / or winding. Each of these intermediate processes can be characterized by various parameters which can relate to the starting product, an intermediate product, the end product, the work stations and / or environmental conditions during the production process 101. These parameters or a subset thereof ultimately characterize the entire production process 101.

A mathematical model 102 of the production process 101 is set up which contains parameters of the production process 101. The model 102 provides a production quantity M = M (x1, ..., xn), where {x1, ..., xn} is a set of parameters going into the model 102 and n is a natural number which indicates the number of parameters considered. The production quantity M preferably relates to the end product. You can z. B. refer to a unit of time or to a certain amount of the end product.

At least one variation parameter xi that is to be varied is selected 103 from the parameter set {x1,..., Xn}, where 1 i n. This is preferably a parameter that is also used in the real production process 101 can be varied within certain limits. The selection 103 of the variation parameter xi can be made manually by an operator or automatically in a computer.

In a next step, the values of the parameters x1,..., Xn are set 104. These are preferably those values that are currently set in the production process 101 to be optimized. A price p per quantity M of the end product, to which the production quantity M relates, is also entered 105. A financial value P - or a total price that can be achieved with the production quantity M (per time unit, per quantity of the starting product, etc.) - is therefore P = p * M.

The selected variation parameter xi is varied 106. For this purpose, a variation Δxi or a new variation parameter value is used xi '= xi + Δxi elected.

From the model 102 and the inputs 103-106 described above, a value difference or change in value .DELTA.P between the financial value P ', which with the varied parameter set {x1, ..., xi + Δxi, ..., xn } is obtained, and the financial value P obtained with the original set of parameters {x1,…, xi, xn} is automatically calculated 107: ΔP = P ́ – P = p · [M (x1, ..., xi + Δxi, ..., xn) –M (x1, ..., xi, ..., xn)] or, in differential notation ,

The value difference .DELTA.P can be positive, negative or zero. A positive difference in value (.DELTA.P> 0) means that a higher price could be achieved with the adoption of the variation .DELTA.xi in the production process 101 than with the original variation parameter xi, and vice versa.

The value difference ΔP is included in an evaluation 108 of the variation Δxi. It can, but does not have to be, the only variable that is taken into account in evaluation 108. Further variables that can be included in the evaluation 108 are e.g. a quality of the end product or a production time, or the corresponding differences between the varied model and the unchanged model. The quality can be estimated from experience or quantified numerically using one or more quality indicators. The evaluation 108 can be carried out by an operator or automatically by a computer.

If the outcome of evaluation 108 is satisfactory, then the new variation parameter value is xi ́ = xi + Δxi Taken 109 in the real textile factory. This optimizes the production process 101. Otherwise, one or more of the inputs 103-106 described above are changed, e.g. a new variation parameter xi and / or a new variation Δxi is selected, and the value difference ΔP is thus calculated 107 again. The transfer 109 can take place manually by an operator or automatically. In the latter case one can arrive at a regulated textile production process 101 in which the variation parameter xi is the controlled variable.

The order of individual steps 103-106 in the exemplary method according to FIG. 1 can be interchanged. So it is e.g. possible to make the choice 103 of the variation parameter xi after entering 105 of the price p per quantity, etc.

As mentioned several times above, certain steps 102-109 of the method according to the invention can be carried out by an operator or automatically by a computer. Both variants can have their uses. However, it could be particularly advantageous to have the choice 103 of the variation parameter xi and / or the choice 106 of the variation Δxi made automatically by a computer. A computer is particularly capable of performing these selection processes. From the given function M (xi, ..., xn) it can numerically find its partial derivatives

calculate for all i = 1, ..., n. At those points where the partial derivatives are large, the greatest effect can be achieved with a variation Δxi. Therefore, such a variation Δxi brings about the most effective optimization.

A plurality of variation parameters xi1, xi2,... Can be selected 103 from the parameter set {xi, xn} and varied 106 at the same time. For the sake of simplicity, the above description relates to a single variation parameter xi, which, however, is not intended to restrict the generality of the invention.

Fig. 2 shows an example of a user interface 2 as used for the method according to the invention on an electronic display unit, e.g. a computer screen, can be provided. The exemplary embodiment relates to the influence of the number of cuts when winding yarn. On the user interface 2 there are fields for inputs and outputs and, optionally, further information. The inputs can be made via an electronic input unit, e.g. a computer mouse or keyboard. The display unit and the input unit can be combined in a sensor screen (touch screen). It is particularly clear, simple and therefore advantageous to display the user interface 2 on a single screen page. This means that all fields for inputs and outputs are visible on the display unit at the same time.

In the embodiment of FIG. 2 there are input fields 211-215 for inputs 104 (see FIG. 1) of five parameter values x1, ..., x5 in an upper part 21 of the user interface. The inputs 104 are made by means of slide controls or by means of numerical entries in input boxes which are attached at the top left. The five parameters are as follows: Input field <sep> Parameter <sep> Symbol <sep> Example value 211 <sep> Winding speed <sep> x1 <sep> 1400 m / min 212 <sep> Average yarn number <sep> x2 <sep> 32 Nec 213 <sep> Weight of the spinning head <sep> x3 <sep> 50 g 214 <sep> Time for creating a splice <sep> x4 <sep> 8 s 215 <sep> Time for changing a spinning head and creating a splice <sep> x5 <sep> 13 s

At the top right there are further input fields 221-224 for inputs 104, 106 of two variation parameters x6, x7 or their variations. These entries can be made using pointers or numerical entries in the corresponding entry boxes. The two variation parameters are as follows: Input fields <sep> Parameter <sep> Symbol <sep> Example value 221, 223 <sep> Number of cuts caused by mass errors <sep> x6 <sep> 25/100 km 222, 224 < sep> Number of cuts caused by contamination <sep> x7 <sep> 35/100 km

For input 106 of the variations Δx6, Δx7, input fields 223, 224 for new or desired values x6 ', x7' of the variation parameters are attached below the input fields 221, 222 for the original parameter values x6, x7. The exemplary new values are: x6 '= 22 cuts / 100 km, x7' = 33 cuts / 100 km.

Below the input fields 223, 224 for the new variation parameters x7 'are input fields 231, 232 for the input 104 of two further parameter values x8, x9, namely: input field <sep> parameter <sep> symbol <sep> exemplary value 231 < sep> Number of operating days per year <sep> x8 <sep> 350 d / y 232 <sep> Number of winding units <sep> x9 <sep> 300

These inputs 104 can be made by means of incremental buttons or by means of numerical entries in corresponding input boxes.

Below the input fields 231, 232 for the two further parameter values x8, x9 there is an input field 241 for the input 105 of a price p per amount of yarn wound, which in the exemplary embodiment of FIG. 2 is 2.5 $ / kg. The price input 105 can take place in the same way as the inputs 104 of the two further parameters x8, x9.

It goes without saying that the parameter values x1,..., X9 can be input in other ways known per se than described above by way of example. The total number of parameters n can differ from the exemplary value 9.

Finally, at the bottom right of the user interface 2 is an output field 251 for the output 107 of an automatically calculated value difference ΔP between the financial value P ', which is with the varied parameter set {x1, ..., x6', x7 ', .. ., x9}, and the financial value P obtained with the original set of parameters {x1, ..., x6, x7, ..., x9}. According to the exemplary embodiment of FIG. 2, the entered reduction in the number of cuts can save $ 91,736 per year.

In addition, further outputs can be provided in the lower left part of the user interface 2. In the exemplary embodiment in FIG. 2, this is a bar chart 260 for various efficiency losses, which are given in percentages. A first column 261 indicates efficiency losses due to spinning heads changes, for example 11%, a second column 262 efficiency losses due to the original cutting numbers, for example 11%, and a third column 263 efficiency losses due to the new cutting numbers, for example 9%. The calculated value difference ΔP results from the increase in efficiency, as can be seen from the comparison between the second 262 and the third 263 column.

A positive value difference (ΔP> 0), as it results in the exemplary embodiment of FIG. 2, does not necessarily have to lead to a transfer 109 of the varied parameter set {x1, x6 ', x7', x9} into the production process 101. Before such a takeover 109 further calculations and / or considerations should be made. These can, in addition to the financial value P, e.g. consider the following aspects: Quality of the end product. The desired reduction in the number of cuts can also change the quality of the yarn produced. The reduction in quality may also result in a reduction in the achievable price p per kilogram of yarn. This could be taken into account in model 102 by providing a further input field (not shown) for the new price p ’per kilogram on user interface 2. Alternatively, a table or a function could be stored in a memory of the executing computer, which assigns the corresponding price p ’per kilogram to each yarn quality (or each set number of cuts). In a preferred embodiment of the invention, however, the choice 103 of the variation parameter xi, the choice of the parameter values x1, ..., xn and / or the choice 106 of the variation Δxi are made so that the quality of the end product remains approximately the same or at least not significantly is decreased. In other words: the method according to the invention is advantageously carried out in a range in which the variation .DELTA.xi causes only a small change .DELTA.Q≈0 in the quality, but the greatest possible change .DELTA.P >> 0 in the financial value. A computer can find such areas particularly well. In this preferred case, the variation Δxi does not affect the price p per quantity. Time required for the production process 101. In the exemplary embodiment of FIG. 2, the time is sufficiently taken into account by the parameters x4 and x5.

Results of calculations for such further aspects can be displayed on the user interface 2 in graphical and / or numerical form.

The choice 103 of the number of cuts x6, x7 as a variation parameter is only one of many possibilities. Examples of further variation parameters xi in a spinning mill are the following: Percentage of noils when combing Number of end breaks in ring spinning Replacement time of the ring traveler during ring spinning Delivery speed of the route Quality of the raw cotton Share of outliers in the yarn during spinning and winding.

Depending on the choice 103 of the at least one variation parameter xi, the parameter set {xi, xn} required for the model 102 can be different. The selection 103 of the at least one variation parameter xi can be made by selecting the corresponding user interface 2. Alternatively, a single user interface 2 can be made available, on which the at least one variation parameter xi is selected.

It goes without saying that the present invention is not restricted to the embodiments discussed above. With knowledge of the invention, the person skilled in the art will be able to derive further variants which also belong to the subject matter of the present invention.

REFERENCE LIST

101 <sep> Production process 102 <sep> Model of the production process 103 <sep> Selection of the variation parameter 104 <sep> Entry of the parameter values 105 <sep> Entry of a price per quantity 106 <sep> Selection of the variation 107 <sep> Calculation the value difference 108 <sep> Evaluation 109 <sep> Transfer of the variation to the production process 2 <sep> User interface 211-215 <sep> Input fields for parameter values 221, 222 <sep> Input fields for original values of the variation parameters 223, 224 <sep> input fields for new values of the variation parameters 231, 232 <sep> input fields for further parameter values 241 <sep> input field for the price per quantity 251 <sep> output field for the value difference 260 <sep> bar chart 261-263 <sep> columns for efficiency losses

Claims (10)

1. A method for optimizing a textile production process (101), in which a textile end product is produced, wherein the production process (101) in a mathematical model (102) having a parameter set ({xi, xn}) with at least one parameter (xi , xn) as an element, at least one variation parameter (xi) from the parameter set ({xi, xn}) in the model (102) is varied by one variation (Δxi) (106), an effect of the at least one variation (Δxi) is valued at a financial value (P) of the final product (108). 2. The method of claim 1, wherein, depending on the outcome of the evaluation (108), the at least one variation (Δxi) in the production process (101) is adopted (109). A method according to any one of the preceding claims, wherein the textile production process (101) is spinning or spooling yarn and the at least one variation parameter (Δxi) is selected from the following amount: number of cuts per yarn length or unit time, proportion of combing on combing , Number of end breaks in ring spinning, replacement time of ring traveler in ring spinning, delivery speed of the line, quality of raw cotton, proportion of outliers in the yarn. 4. The method according to any one of the preceding claims, wherein in addition to the financial value (P) other aspects such as quality of the final product and production time incorporated into the evaluation. 5. The method according to claim 4, wherein a selection of the variation parameter (xi), a selection of the parameter values (xi, ..., xn) and / or a selection (106) of the variation (Δxi) are made such that the quality of the final product remains approximately the same or at least not significantly reduced. 6. Method according to one of the preceding claims, wherein a selection (103) of the at least one variation parameter xi and / or the selection (106) of the at least one variation (Δxi) is carried out automatically by a computer. 7. The method according to any one of the preceding claims, wherein on an electronic display unit, a user interface (2) with fields (211-215, 221-224, 231, 232, 241, 251, 260) is provided for inputs and outputs. 8. The method of claim 7, wherein the user interface (2) is displayed on a single screen page. A computer program product having program code stored on a machine-readable medium for carrying out the method according to one of claims 1 to 8, when the program product runs on a computer. 10. textile operation, which is set up for the execution of a textile production process (101), wherein the textile operation includes a computer on which runs a computer program product according to claim 9.